Disposable monodose inhaler for powdered medicaments

ABSTRACT

A monodose inhaler for powdered medicaments consists of a hollow substantially pipe-shaped body that has a first portion (H), for housing a capsule or cartridge of powdered medicament, defined by a wall (W) in which there are formed slots (S) as air intakes to an inner region where the powder drops, and a second portion (M) connected to the first portion (H) for delivering the medicament by means of a primary stream (F) that carries the powder from the drop region along a delivery duct (D) whose end is suitable to be placed in the patient&#39;s mouth, and it further includes a secondary duct (D′) located under the delivery duct (D) and provided with its own air intake (S′) for delivering a powderless secondary stream (F′). This stream (F′) supports and directs the primary stream (F) so that it can climb over the patient&#39;s tongue, thus preventing the excessive deposition of the medicament in the oropharingeal cavity and obtaining a greater effectiveness of the treatment thanks to the larger amount of medicament that reaches the lungs. Other advantages of this inhaler are the better separation of the drug from the excipient due to the secondary stream (F′) that hits and directs the primary stream (F), and its low cost thanks to the fact that it can be manufactured in plastic by injection molding with a monolithic structure and therefore can be used as a disposable inhaler.

The present invention relates to inhalers for powdered medicaments, and in particular to a disposable monodose inhaler.

It is known that the administration of medicaments in the form of powders to be inhaled is an effective and non-invasive manner to provide a patient with the drug he requires. To this purpose, several devices, generally in the form of reusable multidose inhalers, have been designed to administer powdered medicaments.

This type of inhaler, however, has various drawbacks: a rather high cost; a significant complexity that makes its use rather difficult, in particular for elderly patients; a great difficulty in maintaining it in a satisfactory hygienic state over time; the risk that the powdered medicament is not properly delivered due to thickening or formation of a film caused by humidity or by other factors; the fact that usually most of the medicament does not reach the patient's lungs because it is deposited on the walls of mouth and throat.

In an attempt to overcome these drawbacks there was developed a monodose inhaler, disclosed in U.S. Pat. No. 5,669,378, that has a much simpler and cheaper structure and can therefore be used as a disposable inhaler. In this way there are no risks of poor hygiene and deterioration of the medicament, neither a significant difficulty in use.

In fact this type of inhaler essentially consists of a pipe-shaped body with a first portion, for housing a medicament-containing capsule, connected through a screen to a second portion, for delivering the powder, that the patient puts in his mouth. In order to release the powder from the capsule there is provided a button with a spike suitable to pierce the capsule placed in an adequate supporting member, a button-supporting spring being arranged between the button and the capsule-supporting member to prevent a premature piercing of the capsule.

Although this disposable monodose inhaler is a significant improvement with respect to previous multidose inhalers, yet it is also not free from drawbacks.

First of all, it does not solve the problem of the medicament being deposited in the oropharingeal cavity before reaching the lungs. As a consequence, if the patient does not receive the desired relief that he expects from the medicament, he tends to administer himself another dose prematurely with the risk of various unpleasant side effects caused by the overdose. Moreover, the medicament deposited in the oropharingeal cavity can cause some problems such as soreness, coughing, dryness and the like.

Secondly, it still requires assembling the above-mentioned three members (button, spring, capsule support) in the housing portion, which implies a certain manufacturing cost as well as the risk of a malfunction in case of defective assembly.

Therefore the object of the present invention is to provide a disposable monodose inhaler which is free from said drawbacks. This object is achieved by means of a monolithic inhaler provided with a bottom duct in the delivering portion and suitable to house an autoperforating cartridge.

The main advantage of the present inhaler is given by the presence of the secondary stream, delivered from the bottom duct, that supports and directs the primary stream, which carries the powdered medicament, so that the primary stream can climb over the patient's tongue. In this way there is prevented the excessive deposition of the medicament in the oropharingeal cavity and there is obtained a greater effectiveness of the treatment thanks to the larger amount of medicament that reaches the lungs.

A further advantage provided by the presence of the secondary stream is the better separation of the drug from the excipient (usually lactose) due to the secondary stream that hits and directs the primary stream.

Still another advantage of this inhaler is its low cost, thanks to the fact that notwithstanding the presence of the bottom duct it can still be manufactured in plastic by injection molding with a monolithic structure. Moreover, this inhaler is suitable to house an autoperforating cartridge, like the cartridge disclosed in WO 03/011708 in the name of one of the inventors, whereby the other members for capsule piercing described in the above-mentioned prior art inhaler can be dispensed with.

Further advantages and characteristics of the inhaler according to the present invention will be clear to those skilled in the art from the following detailed description of an embodiment thereof, with reference to the annexed drawings wherein:

1 a FIG. 1 is a front perspective view of the inhaler;

1 a FIG. 2 is a top plan view of the inhaler;

1 a FIG. 3 is a side view of the inhaler;

1 a FIG. 4 is a front view of the inhaler;

1 a FIG. 5 is a rear perspective view of the inhaler; and

1 a FIG. 6 is a sectional rear perspective view taken along the longitudinal midplane of the inhaler.

With reference to said figures, there is seen that an inhaler according to the present invention conventionally consists of a hollow substantially pipe-shaped body that has a first portion H, for housing the capsule or cartridge of the powdered medicament, and a second portion M, for delivering the medicament through a delivery duct D whose end is suitable to be placed in the patient's mouth.

In the wall W that defines the housing portion H there are formed one or more vertical slots S to provide air intakes to the inner region P where the powder drops. In the illustrated embodiment there are provided three slots S, namely a central slot extending through the whole height of wall W at the midplane in distal position and other two shorter slots symmetrically arranged with respect to the central slot.

The connection between the powder drop region P and the delivery duct D is achieved through a grid G sized to prevent the passage of pieces of the capsule or cartridge that should drop therefrom upon release of the powder.

The air entering through slots S forms a stream F that carries the powder from region P, through grid G, along the delivery duct D up to the patient's mouth.

The main novel aspect of the present inhaler is that it is designed to generate also a secondary, powderless, stream F′ that supports and directs the primary stream F upon inhalation.

To this purpose, in the housing portion H there is provided a second wall W′ that encloses wall W at least partially, for example along the rear half of the latter in the illustrated embodiment, and is spaced therefrom so as to obtain an interspace S′ between the two walls.

This interspace S′ continues below the powder drop region P and extends up to the end of the delivery duct D thus forming a bottom duct D′. In practice, the delivering portion M results therefore consisting of two ducts D, D′ one on top of the other separated by a horizontal baffle B.

It is therefore clear that when the patient draws in air to inhale the powder located in region P, where it was released preferably from an autoperforating cartridge as mentioned above, a portion of the air passes through slots S and forms the primary powder-carrying stream F delivered through duct D, while another portion of the air passes through interspace S′ and forms the secondary powderless stream F′ delivered through the secondary duct D′.

As previously mentioned, the secondary stream F′ supports the primary stream F and prevents the powder from depositing, also due to gravity, on the patient's tongue or on other walls of the oropharingeal cavity. This supporting and directing function is particularly important in case the patient holds the distal end of the inhaler too much inclined upwards.

This supporting effect, as well as the other effect of separation of the drug from the excipient, can be increased or decreased by changing the ratio between the cross-sections of ducts D, D′ and/or between the cross-sections of the air intakes S, S′ or other details. In other words, the two streams F, F′ can be adjusted through the design of the various parts of the inhaler in order to obtain several embodiments with different inhalation characteristics for different specific applications.

For example, the air intake S′ for the secondary stream F′ could be formed directly at the rear end of the secondary duct D′, in which case wall W′ would extend only below the powder drop region P. Also, the dividing baffle B could be U-shaped rather than plane, so that the “air cushion” formed by the secondary stream F′ partially encloses the primary stream F also on the sides.

It is clear that the above-described and illustrated embodiment of the inhaler according to the invention is just an example susceptible of various modifications. In particular, although portions H, M have been illustrated as connected at 90° it is clear that the monolithic body of the inhaler can be made also with any other angle between said portions from 0° to 90°, e.g. 45° or 60°. Moreover, the number, shape and arrangement of the air intakes to the powder drop region P can be freely changed and therefore be completely different from the above-illustrated slots S. 

1. Inhaler for powdered medicaments consisting of a hollow substantially pipe-shaped body that has a first portion (H), for housing a capsule or cartridge of powdered medicament, defined by a wall (W) in which there are formed one or more air intakes to an inner region (P) where the powder drops, and a second portion (M) connected to said first portion (H) for delivering the medicament by means of a primary stream (F) that carries the powder from said drop region (P) along a delivery duct (D) whose end is suitable to be placed in the patient's mouth, characterized in that it further includes a secondary duct (D′) located under said delivery duct (D) and provided with its own air intake (S′) for delivering a powderless secondary stream (F′).
 2. Inhaler according to claim 1, characterized in that in the housing portion (H) there is provided a second wall (W′) that encloses at least partially the wall (W) and is spaced therefrom so as to obtain an interspace (S′) that extends below the powder drop region (P) and acts as air intake for the secondary duct
 3. Inhaler according to claim 1 or 2, characterized in that the air intakes to the powder drop region (P) are three slots (S), preferably a central slot extending through the whole height of the wall (W) at the midplane in distal position and other two shorter slots symmetrically arranged with respect to said central slot.
 4. Inhaler according to one of the preceding claims, characterized in that the dividing baffle (B) that separates the delivery duct (D) from the secondary duct (D′) is U-shaped.
 5. Inhaler according to one of the preceding claims, characterized in that a grid (G) is arranged between the powder drop region (P) and the delivery duct (D).
 6. Inhaler according to one of the preceding claims, characterized in that it is manufactured in plastic by injection molding with a monolithic structure.
 7. Inhaler according to one of the preceding claims, characterized in that it is suitable to house an autoperforating cartridge.
 8. Inhaler according to one of the preceding claims, characterized in that the two portions (H, M) of the body are connected at 90°. 